Course-Control, Metabolism and Wing Interference During Ultralong Tethered Flight in Drosophila Melanogaster

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Articles by GÖTZ, K. G.

Journal of Experimental Biology 128,35-46 (1987)
Published by Company of Biologists 1987

Course-Control, Metabolism and Wing Interference During Ultralong Tethered Flight in Drosophila Melanogaster

KARL G. GÖTZ ¹

¹ Max-Planck-Institut für biologische Kybernetik, Spemannstrasse 38, D-7400 Tübingen 1, Federal Republic of Germany

Tethered flight in a 3-day-old female Drosophila was sustainedfor 32.2 h with only short interruptions during uptake of sucrosesolution. The course-control reactions derived from the differenceof the wingbeat amplitudes on either side have been used tosimulate the rotatory displacement of the surrounding landmarksduring a comparable turn in free flight. Stabilization of atarget in the preferred area of the visual field requires continuousvisual attention. A rate of about 5 course-correcting manoeuvresper second was maintained throughout the experiment. Drosophilaseems to be able to cover long distances in search of a favourablehabitat.

Flight-specific carbohydrate consumption is equivalentto a metabolic power input per body weight of about 18 W N^-1.The tethered fly produces about 40 % of the lift required tosustain hovering flight. The resulting mechanochemical efficiencyof about 0.04-0.07 is within the expected order of magnitudefor flying insects. Expenditure of reserve substances may accountfor the difference between the comparatively low power inputof about 7 WN^-1 derived from carbohydrate uptake in the firsthours of flight (Wigglesworth, 1949), and the actual metabolicturnover of about 21WN^-1 derived from oxygen consumption duringthis period (Laurie-Ahlberg et al. 1985).

Weis-Fogh's ‘clapand fling’, a widespread lift-generating process exploitingthe aerodynamic wing interference at the dorsal end of the wingbeat,was in action throughout the flight. However, there were twosignificant modifications (as first conceived by Ellington,1980): (1) during ‘clap’, there is a progress of wingcontact from the leading to the trailing edge, which is likelyto ‘squeeze’ a thrust-generating jet of air to therear; (2) during ‘fling’, there is a progress of wingseparation in the same direction, which is described as a ‘peel’resembling the progressive separation of two plastic foils pulledapart against forces of mutual attraction. The wings of thetest fly survived about 23 million such peels without damage.Increasing airspeed decreases the intensity of ‘clap andfling’ in Drosophila: results obtained in the wind tunnelshow the transition to a ‘near clap and fling’, lackingmutual wing contact.

Key words: Drosophila, flight, vision, course-control, metabolism

Accepted on October 27, 1986

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